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Lecturer PSOE Dan Garcia cs.berkeley/~ddgarcia

inst.eecs.berkeley.edu/~cs61c CS61C : Machine Structures Lecture 10 – Introduction to MIPS Decisions II 2004-02-11. Lecturer PSOE Dan Garcia www.cs.berkeley.edu/~ddgarcia.

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Lecturer PSOE Dan Garcia cs.berkeley/~ddgarcia

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  1. inst.eecs.berkeley.edu/~cs61cCS61C : Machine Structures Lecture 10 – Introduction to MIPS Decisions II2004-02-11 Lecturer PSOE Dan Garcia www.cs.berkeley.edu/~ddgarcia Hubble telescope photo of “Evil Eye”created by a collision ages ago that produced a “dark ring and a roiling, conflicting interior”www.cnn.com/2004/TECH/space/02/06/space.blackeye.reut/

  2. Review • Memory is byte-addressable, but lw and sw access one word at a time. • A pointer (used by lw and sw) is just a memory address, so we can add to it or subtract from it (using offset). • A Decision allows us to decide what to execute at run-time rather than compile-time. • C Decisions are made using conditional statements within if, while, do while, for. • MIPS Decision making instructions are the conditional branches: beq and bne. • New Instructions: lw, sw, beq, bne, j

  3. From last time: Loading, Storing bytes 1/2 • In addition to word data transfers (lw, sw), MIPS has byte data transfers: • load byte: lb • store byte: sb • same format as lw, sw

  4. byteloaded …is copied to “sign-extend” This bit Loading, Storing bytes 2/2 • What do with other 24 bits in the 32 bit register? • lb: sign extends to fill upper 24 bits xxxx xxxx xxxx xxxx xxxx xxxx x zzz zzzz • Normally don't want to sign extend chars • MIPS instruction that doesn't sign extend when loading bytes: load byte unsigned: lbu

  5. Overflow in Arithmetic (1/2) • Reminder: Overflow occurs when there is a mistake in arithmetic due to the limited precision in computers. • Example (4-bit unsigned numbers): +15 1111 +3 0011 +18 10010 • But we don’t have room for 5-bit solution, so the solution would be 0010, which is +2, and wrong.

  6. Overflow in Arithmetic (2/2) • Some languages detect overflow (Ada), some don’t (C) • MIPS solution is 2 kinds of arithmetic instructions to recognize 2 choices: • add (add), add immediate (addi) and subtract (sub) cause overflow to be detected • add unsigned (addu), add immediate unsigned (addiu) and subtract unsigned (subu) do not cause overflow detection • Compiler selects appropriate arithmetic • MIPS C compilers produceaddu, addiu, subu

  7. Two Logic Instructions • 2 lectures ago we saw add, addi, sub • Here are 2 more new instructions • Shift Left: sll $s1,$s2,2#s1=s2<<2 • Store in $s1 the value from $s2 shifted 2 bits to the left, inserting 0’s on right; << in C • Before: 0000 0002hex0000 0000 0000 0000 0000 0000 0000 0010two • After: 0000 0008hex0000 0000 0000 0000 0000 0000 0000 1000two • What arithmetic effect does shift left have? • Shift Right: srl is opposite shift; >>

  8. Loops in C/Assembly (1/3) • Simple loop in C; A[] is an array of ints do { g = g + A[i]; i = i + j; } while (i != h); • Rewrite this as: Loop: g = g + A[i];i = i + j; if (i != h) goto Loop; • Use this mapping:g, h, i, j, base of A$s1, $s2, $s3, $s4, $s5

  9. Loops in C/Assembly (2/3) • Final compiled MIPS code: Loop: sll $t1,$s3,2 #$t1= 4*I add $t1,$t1,$s5#$t1=addr Alw $t1,0($t1) #$t1=A[i]add $s1,$s1,$t1 #g=g+A[i]add $s3,$s3,$s4#i=i+j bne $s3,$s2,Loop# goto Loop# if i!=h • Original code: Loop: g = g + A[i];i = i + j; if (i != h) goto Loop;

  10. Loops in C/Assembly (3/3) • There are three types of loops in C: • while • do… while • for • Each can be rewritten as either of the other two, so the method used in the previous example can be applied to while and for loops as well. • Key Concept: Though there are multiple ways of writing a loop in MIPS, the key to decision making is conditional branch

  11. Inequalities in MIPS (1/3) • Until now, we’ve only tested equalities (== and != in C). General programs need to test < and > as well. • Create a MIPS Inequality Instruction: • “Set on Less Than” • Syntax: slt reg1,reg2,reg3 • Meaning: if (reg2 < reg3) reg1 = 1; else reg1 = 0; • In computereeze, “set” means “set to 1”, “reset” means “set to 0”. reg1 = (reg2 < reg3); Same thing…

  12. Inequalities in MIPS (2/3) • How do we use this? Compile by hand:if (g < h) goto Less;#g:$s0, h:$s1 • Answer: compiled MIPS code… slt $t0,$s0,$s1 # $t0 = 1 ifg<hbne $t0,$0,Less # goto Less# if $t0!=0# (if (g<h)) Less: • Branch if $t0 != 0  (g < h) • Register $0 always contains the value 0, so bne and beq often use it for comparison after an slt instruction.

  13. Inequalities in MIPS (3/3) • Now, we can implement <, but how do we implement >, ≤ and ≥ ? • We could add 3 more instructions, but: • MIPS goal: Simpler is Better • Can we implement ≤ in one or more instructions using just slt and the branches? • What about >? • What about ≥?

  14. Immediates in Inequalities • There is also an immediate version of slt to test against constants: slti • Helpful in for loops if (g >= 1) goto Loop Loop: . . .slti $t0,$s0,1 # $t0 = 1 if# $s0<1 (g<1)beq $t0,$0,Loop# goto Loop# if $t0==0# (if (g>=1)) C MIPS

  15. What about unsigned numbers? • Also unsigned inequality instructions: sltu, sltiu …which set result to 1 or 0 depending on unsigned comparisons • What is value of $t0, $t1? ($s0 = FFFF FFFAhex, $s1 = 0000 FFFAhex) slt $t0, $s0, $s1 sltu $t1, $s0, $s1

  16. MIPS Signed vs. Unsigned – diff meanings! • MIPS Signed v. Unsigned is an “overloaded” term • Do/Don't sign extend(lb, lbu) • Don't overflow(addu, addiu, subu, multu, divu) • Do signed/unsigned compare (slt,slti/sltu,sltiu)

  17. Example: The C Switch Statement (1/3) • Choose among four alternatives depending on whether k has the value 0, 1, 2 or 3. Compile this C code:switch (k) {case 0: f=i+j; break; /* k=0 */case 1: f=g+h; break; /* k=1 */case 2: f=g–h; break; /* k=2 */case 3: f=i–j; break; /* k=3 */}

  18. Example: The C Switch Statement (2/3) • This is complicated, so simplify. • Rewrite it as a chain of if-else statements, which we already know how to compile: if(k==0) f=i+j; else if(k==1) f=g+h; else if(k==2) f=g–h; else if(k==3) f=i–j; • Use this mapping: f: $s0, g: $s1, h: $s2, i: $s3, j: $s4, k: $s5

  19. Example: The C Switch Statement (3/3) • Final compiled MIPS code: bne $s5,$0,L1# branch k!=0add $s0,$s3,$s4 #k==0 so f=i+j j Exit # end of case so ExitL1: addi $t0,$s5,-1 # $t0=k-1 bne $t0,$0,L2# branch k!=1add $s0,$s1,$s2#k==1 so f=g+h j Exit # end of case so ExitL2: addi $t0,$s5,-2 # $t0=k-2 bne $t0,$0,L3# branch k!=2sub $s0,$s1,$s2 #k==2 so f=g-h j Exit# end of case so ExitL3: addi $t0,$s5,-3 # $t0=k-3 bne $t0,$0,Exit# branch k!=3 sub $s0,$s3,$s4 #k==3 so f=i-j Exit:

  20. Peer Instruction What C code properly fills in the blank in loop below? Loop:addi $s0,$s0,-1 # i = i - 1 slti $t0,$s1,2 # $t0 = (j < 2) beq $t0,$0 ,Loop# goto Loop if $t0 == 0 slt $t0,$s1,$s0# $t0 = (j < i) bne $t0,$0 ,Loop# goto Loop if $t0 != 0 ($s0=i,$s1=j) 1: j < 2 && j < i2: j ≥ 2 && j < i3: j < 2 && j ≥ i4: j ≥ 2 && j ≥ i5: j > 2 && j < i6: j < 2 || j < i7: j ≥ 2 || j < i8: j < 2 || j ≥ i9: j ≥ 2 || j ≥ i0: j > 2 || j < i do {i--;} while(__);

  21. “And in conclusion…” • In order to help the conditional branches make decisions concerning inequalities, we introduce a single instruction: “Set on Less Than”called slt, slti, sltu, sltiu • One can store and load (signed and unsigned) bytes as well as words • Unsigned add/sub don’t cause overflow • New MIPS Instructions: sll, srl slt, slti, sltu, sltiu addu, addiu, subu

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